Merit order

Template:Short description Script error: No such module "Distinguish".Template:Government by algorithm The merit order is a way of ranking available sources of energy, especially electrical generation, based on ascending order of price (which may reflect the order of their short-run marginal costs of production) and sometimes pollution, together with amount of energy that will be generated. In a centralized management scheme, the ranking is such that those with the lowest marginal costs are the first sources to be brought online to meet demand, and the plants with the highest marginal costs are the last to be brought on line. Dispatching power generation in this way, known as economic dispatch, minimizes the cost of production of electricity. Sometimes generating units must be started out of merit order, due to transmission congestion, system reliability or other reasons.

In environmental dispatch, additional considerations concerning reduction of pollution further complicate the power dispatch problem. The basic constraints of the economic dispatch problem remain in place but the model is optimized to minimize pollutant emission in addition to minimizing fuel costs and total power loss.^[1]

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The effect of renewable energy on merit order

The high demand for electricity during peak demand pushes up the bidding price for electricity, and the often relatively inexpensive baseload power supply mix is supplemented by 'peaking power plants', which produce electrical power at higher cost, and therefore are priced higher for their electrical output.

Increasing the supply of renewable energy tends to lower the average price per unit of electricity because wind energy and solar energy have very low marginal costs: they do not have to pay for fuel, and the sole contributors to their marginal cost is operations and maintenance. With cost often reduced by feed-in-tariffScript error: No such module "Unsubst". revenue, their electricity is as a result, less costly on the spot market than that from coal or natural gas, and transmission companies typically` buy from them first.^[2][3] Solar and wind electricity therefore substantially reduce the amount of highly priced peak electricity that transmission companies need to buy, during the times when solar/wind power is available, reducing the overall cost. A study by the Fraunhofer Institute ISI found that this "merit order effect" had allowed solar power to reduce the price of electricity on the German energy exchange by 10% on average, and by as much as 40% in the early afternoon. In 2007Template:Update inline; as more solar electricity was fed into the grid, peak prices may come down even further.^[3] By 2006, the "merit order effect" indicated that the savings in electricity costs to German consumers, on average, more than offset the support payments paid by customers for renewable electricity generation.^[3]

A 2013 study estimated the merit order effect of both wind and photovoltaic electricity generation in Germany between the years 2008 and 2012. For each additional GWh of renewables fed into the grid, the price of electricity in the day-ahead market was reduced by 0.11–0.13Script error: No such module "String".¢/kWh. The total merit order effect of wind and photovoltaics ranged from 0.5Script error: No such module "String".¢/kWh in 2010 to more than 1.1Script error: No such module "String".¢/kWh in 2012.^[4]

The near-zero marginal cost of wind and solar energy does not, however, translate into zero marginal cost of peak load electricity in a competitive open electricity market system as wind and solar supply alone often cannot be dispatched to meet peak demand without incurring marginal transmission costs and potentially the costs of ``batteries. The purpose of the merit order dispatching paradigm was to enable the lowest net cost electricity to be dispatched first thus minimising overall electricity system costs to consumers. Intermittent wind and solar is sometimes able to supply this economic function. If peak wind (or solar) supply and peak demand both coincide in time and quantity, the price reduction is larger. On the other hand, solar energy tends to be most abundant at noon, whereas peak demand is late afternoon in warm climates, leading to the so-called duck curve.Script error: No such module "Unsubst".

A 2008 study by the Fraunhofer Institute ISI in Karlsruhe, Germany found that windpower saves German consumers €5Script error: No such module "String".billion a year. It is estimated to have lowered prices in European countries with high wind generation by between 3 and 23Script error: No such module "String".€/MWh.^[5][6] On the other hand, renewable energy in Germany increased the price for electricity, consumers there now pay 52.8 €/MWh more only for renewable energy (see German Renewable Energy Sources Act), average price for electricity in Germany now is increased to 26Script error: No such module "String".¢/kWh. Increasing electrical grid costs for new transmission, market trading and storage associated with wind and solar are not included in the marginal cost of power sources, instead grid costs are combined with source costs at the consumer end.Script error: No such module "Unsubst".

Economic dispatch

Economic dispatch is the short-term determination of the optimal output of a number of electricity generation facilities, to meet the system load, at the lowest possible cost, subject to transmission and operational constraints. The Economic Dispatch Problem can be solved by specialized computer software which should satisfy the operational and system constraints of the available resources and corresponding transmission capabilities. In the US Energy Policy Act of 2005, the term is defined as "the operation of generation facilities to produce energy at the lowest cost to reliably serve consumers, recognising any operational limits of generation and transmission facilities".^[7]

The main idea is that, in order to satisfy the load at a minimum total cost, the set of generators with the lowest marginal costs must be used first, with the marginal cost of the final generator needed to meet load setting the system marginal cost. This is the cost of delivering one additional MWh of energy onto the system. Due to transmission constraints, this cost can vary at different locations within the power grid - these different cost levels are identified as "locational marginal prices" (LMPs). The historic methodology for economic dispatch was developed to manage fossil fuel burning power plants, relying on calculations involving the input/output characteristics of power stations.Script error: No such module "Unsubst".

Basic mathematical formulation

The following is based on an analytical methodology following Biggar and Hesamzadeh (2014)^[8] and Kirschen (2010).^[9] The economic dispatch problem can be thought of as maximising the economic welfare WScript error: No such module "Check for unknown parameters". of a power network whilst meeting system constraints.

For a network with nScript error: No such module "Check for unknown parameters". buses (nodes), suppose that S_kScript error: No such module "Check for unknown parameters". is the rate of generation, and D_kScript error: No such module "Check for unknown parameters". is the rate of consumption at bus kScript error: No such module "Check for unknown parameters".. Suppose, further, that C_k(S_k)Script error: No such module "Check for unknown parameters". is the cost function of producing power (i.e., the rate at which the generator incurs costs when producing at rate S_kScript error: No such module "Check for unknown parameters".), and V_k(D_k)Script error: No such module "Check for unknown parameters". is the rate at which the load receives value or benefits (expressed in currency units) when consuming at rate D_kScript error: No such module "Check for unknown parameters".. The total welfare is then

${\displaystyle W={\displaystyle \sum _{k=1}^n}{V}_k(D_k)-{\displaystyle \sum _{k=1}^n}{C}_k(S_k)}$

The economic dispatch task is to find the combination of rates of production and consumption (S_k, D_kScript error: No such module "Check for unknown parameters".) which maximise this expression WScript error: No such module "Check for unknown parameters". subject to a number of constraints:

${\displaystyle \underset{S_k,D_k}{\max }W}$

The first constraint, which is necessary to interpret the constraints that follow, is that the net injection at each bus is equal to the total production at that bus less the total consumption:

${\displaystyle \mathrm{\forall }k,I_k=S_k-D_k}$

The power balance constraint requires that the sum of the net injections at all buses must be equal to the power losses in the branches of the network:

${\displaystyle {\displaystyle \sum _{k=1}^n}{I}_k=L(I_1,I_2,\dots ,I_{n-1})}$

The power losses LScript error: No such module "Check for unknown parameters". depend on the flows in the branches and thus on the net injections as shown in the above equation. However it cannot depend on the injections on all the buses as this would give an over-determined system. Thus one bus is chosen as the Slack bus and is omitted from the variables of the function LScript error: No such module "Check for unknown parameters".. The choice of Slack bus is entirely arbitrary, here bus nScript error: No such module "Check for unknown parameters". is chosen.

The second constraint involves capacity constraints on the flow on network lines. For a system with mScript error: No such module "Check for unknown parameters". lines this constraint is modeled as:

${\displaystyle F_l(I_1,I_2,\dots ,I_{n-1})\le F_l^{max}l=1,\dots ,m}$

where F_lScript error: No such module "Check for unknown parameters". is the flow on branch lScript error: No such module "Check for unknown parameters"., and F_l^maxScript error: No such module "Check for unknown parameters". is the maximum value that this flow is allowed to take. Note that the net injection at the slack bus is not included in this equation for the same reasons as above.

These equations can now be combined to build the Lagrangian of the optimization problem:

${\displaystyle {ℒ}={\displaystyle \sum _{k=1}^n}{C}_k(I_k)+\pi [L(I_1,I_2,\dots ,I_{n-1})-{\displaystyle \sum _{k=1}^n}{I}_k]+{\displaystyle \sum _{l=1}^m}{\mu }_l[F_l^{max}-F_l(I_1,I_2,\dots ,I_{n-1})]}$

where π and μ are the Lagrangian multipliers of the constraints. The conditions for optimality are then:

${\displaystyle \frac{\partial {ℒ}}{\partial I_k}=0k=1,\dots ,n}$

${\displaystyle \frac{\partial {ℒ}}{\partial \pi }=0}$

${\displaystyle \frac{\partial {ℒ}}{\partial {\mu }_l}=0l=1,\dots ,m}$

${\displaystyle {\mu }_l\cdot [F_l^{max}-F_l(I_1,I_2,\dots ,I_{n-1})]=0{\mu }_l\ge 0k=1,\dots ,n}$

where the last condition is needed to handle the inequality constraint on line capacity.

Solving these equations is computationally difficult as they are nonlinear and implicitly involve the solution of the power flow equations. The analysis can be simplified using a linearised model called a DC power flow.

There is a special case which is found in much of the literature. This is the case in which demand is assumed to be perfectly inelastic (i.e., unresponsive to price). This is equivalent to assuming that ${\displaystyle V_k(D_k)=M\min (D_k,{\overline{D}}_k)}$ for some very large value of ${\displaystyle M}$ and inelastic demand ${\displaystyle {\overline{D}}_k}$. Under this assumption, the total economic welfare is maximised by choosing ${\displaystyle D_k={\overline{D}}_k}$. The economic dispatch task reduces to:

${\displaystyle \underset{S_k}{\min }{\displaystyle \sum _{k=1}^n}{C}_k(S_k)}$

Subject to the constraint that ${\displaystyle \mathrm{\forall }k,I_k=S_k-{\overline{D}}_k}$ and the other constraints set out above.

Environmental dispatch

In environmental dispatch, additional considerations concerning reduction of pollution further complicate the power dispatch problem. The basic constraints of the economic dispatch problem remain in place but the model is optimized to minimize pollutant emission in addition to minimizing fuel costs and total power loss.^[1] Due to the added complexity, a number of algorithms have been employed to optimize this environmental/economic dispatch problem. Notably, a modified bees algorithm implementing chaotic modeling principles was successfully applied not only in silico, but also on a physical model system of generators.^[1] Other methods used to address the economic emission dispatch problem include Particle Swarm Optimization (PSO)^[10] and neural networks^[11]

Another notable algorithm combination is used in a real-time emissions tool called Locational Emissions Estimation Methodology (LEEM) that links electric power consumption and the resulting pollutant emissions.^[12] The LEEM estimates changes in emissions associated with incremental changes in power demand derived from the locational marginal price (LMP) information from the independent system operators (ISOs) and emissions data from the US Environmental Protection Agency (EPA).^[12] LEEM was developed at Wayne State University as part of a project aimed at optimizing water transmission systems in Detroit, MI starting in 2010 and has since found a wider application as a load profile management tool that can help reduce generation costs and emissions.^[13]

References

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External links

• Economic Dispatch: Concepts, Practices and Issues

See also

• Electricity market
• Bid-based, security-constrained, economic dispatch with nodal prices
• Unit commitment problem in electrical power production
• German Renewable Energy Sources Act

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